考虑条件风险价值的公路交通能源系统多能流管控策略

doi:10.19595/j.cnki.1000-6753.tces.231461

摘要
图/表
参考文献
相关文章 (15)

全文: PDF (5685 KB) HTML
输出: BibTeX | EndNote (RIS)

摘要为了实现公路交通背景下多能源系统和电动汽车换电站的经济运行与利益共赢,该文提出考虑条件风险价值（CVaR）的公路交通能源系统（HTES）多能流管控策略。首先,建立了主从博弈双层优化模型,其中上层模型以最小化HTES的综合成本为目标,对其进行多能流的合理管控与优化定价;在下层模型中,换电站根据HTES制定的价格灵活地调整各电池的充放电功率,在满足电能需求的前提下最小化与HTES进行能量交互的成本。然后基于多场景法,引入CVaR衡量可再生能源出力的不确定性所带来的风险成本,利用Karush-Kuhn-Tucker(KKT)条件和强对偶定理将原主从博弈双层模型转换为单层混合整数线性规划问题以计算其纳什均衡解,进而获取最优的运行和定价方案。最后,进行算例仿真。结果表明,所提策略可以兼顾HTES和换电站不同主体间的经济利益,实现运行成本和风险成本的平衡。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	苏粟
	韦存昊
	聂晓波
	李玉璟
	王磊

关键词 ：条件风险价值, 主从博弈, 多能流管控, 公路交通能源系统, 换电站

Abstract：To steadily promote carbon reduction policies, the development of electric vehicles (EVs) is currently experiencing a period of rapid growth. As a result, incorporating EV battery swapping stations into the highway traffic infrastructure has become one of the means to alleviate range anxiety and meet the fast charge-replenishment needs of EV users during long-distance driving. However, the introduction of battery swapping stations has also brought new challenges to the energy management and economic operation of highway traffic energy systems (HTES). Considering the unique application scenario of highway traffic, there is still a lack of comprehensive exploration regarding the complex relationship between HTES and battery swapping stations, as well as the joint operation and interaction mode between them. To address these gaps, this paper proposes a multi-energy flow management and control strategy for HTES considering conditional value-at-risk (CVaR). By taking into account the benefits of both HTES and battery swapping stations, as well as the uncertainty of renewable energy, this strategy aims to provide energy management and optimized pricing solutions.
Firstly, a Stackelberg game bilevel optimization model is established. In the upper level of the established model, the reasonable control of multi-energy flows and optimal pricing are carried out to minimize the comprehensive cost of HTES. In the lower level, the battery swapping station flexibly schedules the charging and discharging power of each battery according to the price set by HTES, and then minimizes the cost of energy interaction with HTES on the premise of meeting the power demand. Next, based on the multi-scenario method, CVaR is introduced to measure the risk cost caused by the uncertainty of renewable energy output. Then, using the Karush-Kuhn-Tucker condition and strong duality theorem, the original Stackelberg game bilevel model is transformed into a single-layer mixed integer linear programming problem to solve the Nash equilibrium solution, and hence the optimal operation and pricing scheme is obtained.
Simulation results on a highway service area show that the cost of HTES will increase without participation in the electrolytic tank, fuel cell, hydrogen storage tank and energy storage system, but it will have little impact on the charging and discharging costs of the battery swapping station. Due to wider access ways in electricity compared to hydrogen, power-hydrogen conversion equipment tends to respond more to changes in hydrogen prices. Scenarios without an electrolytic tank have higher costs than those without a fuel cell. Moreover, expanding the pricing range of HTES can improve its pricing flexibility, allowing it to gain more benefits from the charging and discharging behavior of the battery swapping station. This can result in a decrease in the HTES cost and an increase in the battery swapping station cost. If the flexible charging and discharging duration of batteries is increased from 5 hours to 9 hours in the typical day scenario, it can reduce the charging and discharging cost of the battery swapping station by 17.3% and the HTES comprehensive cost by 1.1%. Regarding the analysis of conservation, increasing the risk aversion coefficient from 0.1 to 0.9 will result in a 0.39% decrease in CVaR under the typical day scenario, while the operating cost of HTES will increase by 0.24%. In the holiday scenario, CVaR will correspondingly decrease by 0.26%, while the operating cost of HTES will increase by 0.30%.
The simulation analysis yields the following conclusions: (1) The participation of power-hydrogen conversion equipment, hydrogen storage tank, and energy storage system can effectively improve the energy supply flexibility of HTES, thereby reducing the economic cost of HTES. (2) Expanding the allowed range of charging and discharging prices set by HTES can to some extent reduce the cost of HTES, but it will correspondingly increase the cost of the battery swapping station. If the flexible charging and discharging duration of batteries in the battery swapping station is extended, it can simultaneously reduce the economic costs of HTES and the battery swapping station. However, the duration will be limited by realistic factors such as passenger flow. (3) By adjusting the risk aversion coefficient, strategies with different conservative levels can be formulated to adapt to different operating styles. In summary, the proposed strategy can achieve a win-win situation for different entities and balance the operation cost and risk cost for HTES.

Key words： Conditional value-at-risk Stackelberg game multi-energy flow management and control highway traffic energy system battery swapping station

收稿日期: 2023-09-05

PACS:	TM73
	TK01

基金资助:国家重点研发计划资助项目（2021YFB2601403）

通讯作者: 韦存昊, 男,1997年生,博士研究生,研究方向为综合能源系统的能量管理与调度、配电网负荷恢复与韧性提升。E-mail：cunhaowei@bjtu.edu.cn

作者简介: 苏粟, 女,1981年生,教授,博士生导师,研究方向为电动汽车与电网互动、V2G能量管理与优化调度。E-mail：ssu@bjtu.edu.cn

引用本文:

苏粟, 韦存昊, 聂晓波, 李玉璟, 王磊. 考虑条件风险价值的公路交通能源系统多能流管控策略[J]. 电工技术学报, 2024, 39(21): 6834-6849. Su Su, Wei Cunhao, Nie Xiaobo, Li Yujing, Wang Lei. Multi-Energy Flow Management and Control Strategy for Highway Traffic Energy System Considering Conditional-Value-at-Risk. Transactions of China Electrotechnical Society, 2024, 39(21): 6834-6849.

链接本文:

https://dgjsxb.ces-transaction.com/CN/10.19595/j.cnki.1000-6753.tces.231461 https://dgjsxb.ces-transaction.com/CN/Y2024/V39/I21/6834

[1] 魏泓屹, 卓振宇, 张宁, 等. 中国电力系统碳达峰·碳中和转型路径优化与影响因素分析[J]. 电力系统自动化, 2022, 46(19): 1-12.
Wei Hongyi, Zhuo Zhenyu, Zhang Ning, et al.Transition path optimization and influencing factor analysis of carbon emission peak and carbon neutrality for power system of China[J]. Automation of Electric Power Systems, 2022, 46(19): 1-12.
[2] 李晓易, 谭晓雨, 吴睿, 等. 交通运输领域碳达峰、碳中和路径研究[J]. 中国工程科学, 2021, 23(6): 15-21.
Li Xiaoyi, Tan Xiaoyu, Wu Rui, et al.Paths for carbon peak and carbon neutrality in transport sector in China[J]. Strategic Study of CAE, 2021, 23(6): 15-21.
[3] 房宇轩, 胡俊杰, 马文帅. 计及用户意愿的电动汽车聚合商主从博弈优化调度策略[J]. 电工技术学报, 2024, 39(16): 5091-5103.
Fang Yuxuan, Hu Junjie, Ma Wenshuai.Optimal dispatch strategy for electric vehicle aggregators based on Stackelberg game theory considering user intention[J]. Transactions of China Electrotechnical Society, 2024, 39(16): 5091-5103.
[4] Ma Zhoujun, Zheng Yuping, Mu Chenlu, et al.Optimal trading strategy for integrated energy company based on integrated demand response considering load classifications[J]. International Journal of Electrical Power & Energy Systems, 2021, 128: 106673.
[5] 滕云, 闫佳佳, 回茜, 等. “无废” 电-氢充能服务区多源微网优化运行模型[J]. 中国电机工程学报, 2021, 41(6): 2074-2088.
Teng Yun, Yan Jiajia, Hui Qian, et al.Optimization operation model of “zero-waste” electricity-hydrogen charging service area multi-energy microgrid[J]. Proceedings of the CSEE, 2021, 41(6): 2074-2088.
[6] Luo Fengzhang, Shao Jingpeng, Jiao Zheng, et al.Research on optimal allocation strategy of multiple energy storage in regional integrated energy system based on operation benefit increment[J]. International Journal of Electrical Power & Energy Systems, 2021, 125: 106376.
[7] 徐艳春, 刘海权, 孙思涵, 等. 计及混合能源共享站的多微网系统双层混合整数规划[J]. 中国电机工程学报, 2023, 43(23): 9136-9149.
Xu Yanchun, Liu Haiquan, Sun Sihan, et al.The bi-level mixed integer programming of multi-microgrid system considering the hybrid energy sharing station[J]. Proceedings of the CSEE, 2023, 43(23): 9136-9149.
[8] 王飚, 赵微微, 林少军, 等. 基于改进的多目标量子遗传算法的高速服务区综合能源管理[J]. 电网技术, 2022, 46(5): 1742-1751.
Wang Biao, Zhao Weiwei, Lin Shaojun, et al.Integrated energy management of highway service area based on improved multi-objective quantum genetic algorithm[J]. Power System Technology, 2022, 46(5): 1742-1751.
[9] Mediwaththe C P, Blackhall L.Network-aware demand-side management framework with A community energy storage system considering voltage constraints[J]. IEEE Transactions on Power Systems, 2021, 36(2): 1229-1238.
[10] Aguiar N, Dubey A, Gupta V.Network-constrained stackelberg game for pricing demand flexibility in power distribution systems[J]. IEEE Transactions on Smart Grid, 2021, 12(5): 4049-4058.
[11] 帅轩越, 马志程, 王秀丽, 等. 基于主从博弈理论的共享储能与综合能源微网优化运行研究[J]. 电网技术, 2023, 47(2): 679-690.
Shuai Xuanyue, Ma Zhicheng, Wang Xiuli, et al.Optimal operation of shared energy storage and integrated energy microgrid based on leader-follower game theory[J]. Power System Technology, 2023, 47(2): 679-690.
[12] Zhang Rufeng, Li Guoqing, Jiang Tao, et al.Incorporating production task scheduling in energy management of an industrial microgrid: a regret-based stochastic programming approach[J]. IEEE Transactions on Power Systems, 2021, 36(3): 2663-2673.
[13] Wang Haibing, Wang Chengmin, Khan M Q, et al.Risk-averse market clearing for coupled electricity, natural gas and district heating system[J]. CSEE Journal of Power and Energy Systems, 2019, 5(2): 240-248.
[14] Li Zhengmao, Wu Lei, Xu Yan.Risk-averse coordinated operation of a multi-energy microgrid considering voltage/var control and thermal flow: an adaptive stochastic approach[J]. IEEE Transactions on Smart Grid, 2021, 12(5): 3914-3927.
[15] 郭怿, 明波, 黄强, 等. 考虑输电功率平稳性的水-风-光-储多能互补日前鲁棒优化调度[J]. 电工技术学报, 2023, 38(9): 2350-2363.
Guo Yi, Ming Bo, Huang Qiang, et al.Day-ahead robust optimal scheduling of hydro-wind-PV-storage complementary system considering the steadiness of power delivery[J]. Transactions of China Electrote-chnical Society, 2023, 38(9): 2350-2363.
[16] 魏韡, 陈玥, 刘锋, 等. 基于主从博弈的智能小区代理商定价策略及电动汽车充电管理[J]. 电网技术, 2015, 39(4): 939-945.
Wei Wei, Chen Yue, Liu Feng, et al.Stackelberg game based retailer pricing scheme and EV charging management in smart residential area[J]. Power System Technology, 2015, 39(4): 939-945.
[17] Rashidizadeh-Kermani H, Vahedipour-Dahraie M, Shafie-Khah M, et al.A regret-based stochastic Bi-level framework for scheduling of DR aggregator under uncertainties[J]. IEEE Transactions on Smart Grid, 2020, 11(4): 3171-3184.
[18] 李军徽, 安晨宇, 李翠萍, 等. 计及调峰市场交易的储能-新能源-火电多目标优化调度[J]. 电工技术学报, 2023, 38(23): 6391-6406.
Li Junhui, An Chenyu, Li Cuiping, et al.Multi-objective optimization scheduling method considering peak regulating market transactions for energy storage-new energy-thermal power[J]. Transactions of China Electrotechnical Society, 2023, 38(23): 6391-6406.
[19] 潘郑楠, 邓长虹, 徐慧慧, 等. 考虑灵活性补偿的高比例风电与多元灵活性资源博弈优化调度[J]. 电工技术学报, 2023, 38(增刊1): 56-69.
Pan Zhengnan, Deng Changhong, Xu Huihui, et al.Game optimal scheduling of high proportion wind power and multiple flexible resources considering flexibility compensation[J]. Transactions of China Electrotechnical Society, 2023, 38(S1): 56-69.
[20] 马腾飞, 裴玮, 肖浩, 等. 基于纳什谈判理论的风-光-氢多主体能源系统合作运行方法[J]. 中国电机工程学报, 2021, 41(1): 25-39, 395.
Ma Tengfei, Pei Wei, Xiao Hao, et al.Cooperative operation method for wind-solar-hydrogen multi-agent energy system based on Nash bargaining theory[J]. Proceedings of the CSEE, 2021, 41(1): 25-39, 395.
[21] Fu Chen, Lin Jin, Song Yonghua, et al.Optimal operation of an integrated energy system incorporated with HCNG distribution networks[J]. IEEE Transactions on Sustainable Energy, 2020, 11(4): 2141-2151.
[22] Zhang Rufeng, Jiang Tao, Li Guoqing, et al.Stochastic optimal energy management and pricing for load serving entity with aggregated TCLs of smart buildings: a stackelberg game approach[J]. IEEE Transactions on Industrial Informatics, 2021, 17(3): 1821-1830.
[23] 李媛, 冯昌森, 文福拴, 等. 含电动汽车和电转气的园区能源互联网能源定价与管理[J]. 电力系统自动化, 2018, 42(16): 1-10.
Li Yuan, Feng Changsen, Wen Fushuan, et al.Energy pricing and management for park-level energy internets with electric vehicles and power-to-gas devices[J]. Automation of Electric Power Systems, 2018, 42(16): 1-10.
[24] 孙毅, 李飞, 胡亚杰, 等. 计及条件风险价值和综合需求响应的产消者能量共享激励策略[J]. 电工技术学报, 2023, 38(9): 2448-2463.
Sun Yi, Li Fei, Hu Yajie, et al.Energy sharing incentive strategy of prosumers considering conditional value at risk and integrated demand response[J]. Transactions of China Electrotechnical Society, 2023, 38(9): 2448-2463.
[25] Yin Yue, He Chuan, Liu Tianqi, et al.Risk-averse stochastic midterm scheduling of thermal-hydro-wind system: a network-constrained clustered unit commitment approach[J]. IEEE Transactions on Sustainable Energy, 2022, 13(3): 1293-1304.
[26] 李康平. 高渗透率分布式光伏下需求响应基线负荷估计方法研究[D]. 北京: 华北电力大学, 2020.
Li Kangping.Research on demand response baseline load estimation method under high penetration of distributed photovoltaics[D]. Beijing: North China Electric Power University, 2020.
[27] Su Su, Li Zening, Jin Xiaolong, et al.Bi-level energy management and pricing for community energy retailer incorporating smart buildings based on chance-constrained programming[J]. International Journal of Electrical Power & Energy Systems, 2022, 138: 107894.
[28] 李亚鹏, 赵麟, 王祥祯, 等. 不确定碳-电耦合市场下梯级水电双层竞价模型[J]. 电力系统自动化, 2023, 47(20): 83-94.
Li Yapeng, Zhao Lin, Wang Xiangzhen, et al.Bi-level bidding model for cascaded hydropower under uncertain carbon-electricity coupled market[J]. Automation of Electric Power Systems, 2023, 47(20): 83-94.